Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring

Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring

Clathrate hydrates are inclusion compounds in which guest molecules are trapped in a host lattice formed by water molecules. They are considered an interesting option for future energy supply and storage technologies. In the current paper, time lapse 3D micro computed tomographic (µCT) imaging with...

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Main Authors: Stefan Arzbacher, Jörg Petrasch, Alexander Ostermann, Thomas Loerting
Format: Article
Language:English
Published: MDPI AG 2016-08-01
Series:Materials
Subjects:
micro-computed X-ray tomography (µCT)
clathrate hydrates
ice
Online Access:http://www.mdpi.com/1996-1944/9/8/668
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spelling doaj-09f3c1ee7f0b4f45992967c5e0fc945f2020-11-25T01:50:26ZengMDPI AGMaterials1996-19442016-08-019866810.3390/ma9080668ma9080668Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic MonitoringStefan Arzbacher0Jörg Petrasch1Alexander Ostermann2Thomas Loerting3Illwerke VKW Professorship for Energy Efficiency, Vorarlberg University of Applied Sciences, Hochschulstraße 1, Dornbirn 6850, AustriaIllwerke VKW Professorship for Energy Efficiency, Vorarlberg University of Applied Sciences, Hochschulstraße 1, Dornbirn 6850, AustriaDepartment of Mathematics, University of Innsbruck, Technikerstraße 13, Innsbruck 6020, AustriaInstitute of Physical Chemistry, University of Innsbruck, Innrain 80–82, Innsbruck 6020, AustriaClathrate hydrates are inclusion compounds in which guest molecules are trapped in a host lattice formed by water molecules. They are considered an interesting option for future energy supply and storage technologies. In the current paper, time lapse 3D micro computed tomographic (µCT) imaging with ice and tetrahydrofuran (THF) clathrate hydrate particles is carried out in conjunction with an accurate temperature control and pressure monitoring. µCT imaging reveals similar behavior of the ice and the THF clathrate hydrate at low temperatures while at higher temperatures (3 K below the melting point), significant differences can be observed. Strong indications for micropores are found in the ice as well as the THF clathrate hydrate. They are stable in the ice while unstable in the clathrate hydrate at temperatures slightly below the melting point. Significant transformations in surface and bulk structure can be observed within the full temperature range investigated in both the ice and the THF clathrate hydrate. Additionally, our results point towards an uptake of molecular nitrogen in the THF clathrate hydrate at ambient pressures and temperatures from 230 K to 271 K.http://www.mdpi.com/1996-1944/9/8/668micro-computed X-ray tomography (µCT)clathrate hydratesice
collection DOAJ
language English
format Article
sources DOAJ
author Stefan Arzbacher
Jörg Petrasch
Alexander Ostermann
Thomas Loerting
spellingShingle Stefan Arzbacher
Jörg Petrasch
Alexander Ostermann
Thomas Loerting
Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
Materials
micro-computed X-ray tomography (µCT)
clathrate hydrates
ice
author_facet Stefan Arzbacher
Jörg Petrasch
Alexander Ostermann
Thomas Loerting
author_sort Stefan Arzbacher
title Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
title_short Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
title_full Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
title_fullStr Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
title_full_unstemmed Micro-Tomographic Investigation of Ice and Clathrate Formation and Decomposition under Thermodynamic Monitoring
title_sort micro-tomographic investigation of ice and clathrate formation and decomposition under thermodynamic monitoring
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2016-08-01
description Clathrate hydrates are inclusion compounds in which guest molecules are trapped in a host lattice formed by water molecules. They are considered an interesting option for future energy supply and storage technologies. In the current paper, time lapse 3D micro computed tomographic (µCT) imaging with ice and tetrahydrofuran (THF) clathrate hydrate particles is carried out in conjunction with an accurate temperature control and pressure monitoring. µCT imaging reveals similar behavior of the ice and the THF clathrate hydrate at low temperatures while at higher temperatures (3 K below the melting point), significant differences can be observed. Strong indications for micropores are found in the ice as well as the THF clathrate hydrate. They are stable in the ice while unstable in the clathrate hydrate at temperatures slightly below the melting point. Significant transformations in surface and bulk structure can be observed within the full temperature range investigated in both the ice and the THF clathrate hydrate. Additionally, our results point towards an uptake of molecular nitrogen in the THF clathrate hydrate at ambient pressures and temperatures from 230 K to 271 K.
topic micro-computed X-ray tomography (µCT)
clathrate hydrates
ice
url http://www.mdpi.com/1996-1944/9/8/668
work_keys_str_mv AT stefanarzbacher microtomographicinvestigationoficeandclathrateformationanddecompositionunderthermodynamicmonitoring
AT jorgpetrasch microtomographicinvestigationoficeandclathrateformationanddecompositionunderthermodynamicmonitoring
AT alexanderostermann microtomographicinvestigationoficeandclathrateformationanddecompositionunderthermodynamicmonitoring
AT thomasloerting microtomographicinvestigationoficeandclathrateformationanddecompositionunderthermodynamicmonitoring
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